Heating circuit for reaction cells



July 13, 1954 Filed March 15, 1951 R. GILMONT ET AL HEATING CIRCUIT FOR REACTION CELLS 5 Shegts-Sheet 1 INVENTORS ROGER GILMONT YMORRIS B J. SCH RTZ 91 ATTORNEY J y 1954 R. IGILMONT ET AL 2,683,793

HEATING CIRCUIT FOR REACTION CELLS Filed March 15, 1951 5 Sheets-Sheet 2 FIG. 3. F flNVENTORS ROGER GILMONT J. SC Z,

ATTORNEY July 13, 1954 Filed March 15, 1951 R. GILMONT ETAL HEATING CIRCUIT FOR REACTION CELLS 5 Sheets-Sheet 3 INVENTORS noesn GILMONT YMORRIS a. SCHWARTZ ATTORN EY 3, 1954 R. GILMONT ETAL 2,683,793

HEATING CIRCUIT FOR REACTION CELLS Filed March 15, 1951 5 Sheets-Sheet 4 MORRIS SCH Z Y TTORNEY July 13, 1954 R. GILMONT ETAL 2,683,793

HEATING CIRCUIT FOR REACTION CELLS Filed March 15, 1951 5 Sheets-Sheet 5 J 1674 66: 134 167: 166i 1167C FIG I6 1 1 z 1671 E ELECTRIC I RECORDER I I I I I K v I flat/r72 1 1 1 1,

72 3 I n 9 I I v; 11 m 124 91 I I i 1 -16; v I 196 .163 ACH AC6 3m VACUUM Ac SUPPLY f PUMP 20/ INVENTORS ROGER GILMONT MORRIS J. SCH T2 9% Q ATTORNEY Patented July 13, 1954 HEATING CIRCUIT FOR REACTION CELLS Roger Gilmont and Morris J. Schwartz, Brooklyn,

N. Y., assignors to Benjamin Cooper, Brooklyn, N. Y.

Application March 15, 1951, Serial No. 215,848

8 Claims.

This invention relates to an improved apparatus for the continuous quantitative determination of combustible gases and is particularly directed to an apparatus for determining the quantity of carbon monoxide present in although it can also be used for quantitatively measuring the content of other gases in air.

It has long been recognized that carbon monoxide is a deadly gas, even in very small con centrations. It is a great hazard as it is produced in many industrial operations and by internal combustion engines. It gives no warning as it is colorless and odorless and diffuses readily, having about the same density as air.

In the Bureau oi Mines Technical Paper No. 355 there is described a carbon monoxide analyzer device including essentially a sample purifying apparatus, a flow regulator and flow meter, a reaction cell heated to a temperature oi 106 C. and containing a therrnopile to measure the heat of oxidation of carbon monoxide in the presence of Hopcalite as a catalyst, and a gas pump for continuously circulating the tested gas through the system. Gas flow was controlled and measured by water containing devices and the operating temperature of 100 C. was produced by a steam bath. The principal difficulties with this type of apparatus were that great care and attention was required to keep the steam bath and the water operated gas flow devices in proper working order despite the adverse eiiects of evaporation and, in the case of the steam bath, boiling off. The present invention relates to improvements in such a device resulting in a practical, rugged and easily maintained gas analyzer.

It is accordingly one object of this invention to provide an apparatus of the character :described wherein the reaction cell unit is within a thermostatically controlled electrically heated metal It is another object of this invention to provide an apparatus of the character described wherein control and metering of the sample gas flow is accomplished without the use of devices containing water or similar liquids.

It is another object of this invention to provide an improved sensitive device of the character described capable of accurately and continuously measuring small quantities of carbon monoxide present in air so thatcorrective ventilation measures can be taken to insure a non-toxic air condition in an enclosed space at all times.

It is another object of this invention to provide an improved apparatus for quantitatively measuring the presence of combustible gases such as hydrogen and methane in air.

It is another object of this invention to provide a device of the character described comprising comparatively few and simple parts, which shall be relatively inexpensive to manufacture and maintain, and which shall nevertheless be practical and efficient to a high degree in use.

Other objects of this invention will in part be obvious and in part hereinbelow pointed out.

The invention accordingly consists in the features of construction, combination of elements and arrangement of parts which will be exemplified in the construction hereinafter described and of which the scope of application will be indicated in the appended claims.

In the accompanying drawings, in which one of the various possible illustrative embodiments of this invention is shown,

Fig. 1 shows .a rear elevational view of a gas analyzer panel embodying this invention;

Fig. 2 shows a front .elevational view of same;

Fig. 3 shows a side elevational view taken on line 33 of Fig. 1;

Fig. 4 is a cross-sectional View taken on line 4-4 of Fig. 3; showing the reaction cell heater with the reaction cell in place;

Fig.5 is a horizontal cross-sectional view taken on line 55 of Fig. 4.;

Fig. 6 is a horizontal cross-sectional view taken on line 6-6 of Fig. a;

Fig. 7 is an enlarged partial view of Fig. 4 showing the slide fit connection between the sample gas line in the heater block and the reaction cell unit;

Fig. 8 is an assembly view of the reaction cell unit;

Fig. 9 is a cross-sectional view taken on line -99 of Fig. 8;

Fig. 10 is a cross-sectional view taken on line l0l0 of Fig. 9;

Fig. 11 is a vertical cross-sectional view of the charcoal filter unit taken on line I l-l l of Fig. 1.

Fig. 12 is a cross-sectional view taken on line l2l2 of Fig. 11;

Fig. 13 is a cross-sectional view of the steelwool and glass-wool filter unit taken on line i3i3 of Fig. 1;

Fig. 14 is a cross-sectional view of the orifice block taken on line Ifll4 of Fig. 3;

Fig. 15 is a partial sectional view taken on line l5l5 of Fig. 5;

Fig. 16 is a schematic diagram of the electric circuits associated with the carbon monoxide analyzer panel; and Fig. 17 is a modification of Fig. 9 showing distributed thermocouple junctions and fiber glass insulation around the thermopile assembly.

Referring now to the drawings, A designates a gas analyzer panel embodying the invention. A brief description of its operation is as follows: The motor driver rotary vacuum pump P draws a sample of air to be analyzed through a sampling line S, thence through filter units M and N, wherein objectionable impurities such as dust, oil particles and certain hydrocarbon vapors are removed, thence through orifice block Q and Cartesian manostat C, serving in combination to regulate the rate of fiow of the sample gas through the apparatus to about 8.5 liters per minute. Measurement of the flow rate for adjustment and monitoring purposes is indicated by a fiowmeter F following the fiow regulator apparatus. From the fiowmeter the gas sample passes into a thermostatically controlled heater block H, wherein it is heated and passed through a Hopcalite type reaction unit centrally located in the heater block. The use of Hopcalite as a catalyst in gas measuring apparatus is well known in the art.

As hereinbelow detailed, said cell contains a thermopile furnishing an output voltage proportional to the carbon monoxide concentration in the sample gas. This output voltage circuit is connected to a sensitive recording device R serving to transcribe a continuous record of the Considering now the detailed construction of the analyzer, the same comprises an upright rectangular steel panel having a rear face H, a front face I2, and a rearwardly extending peripheral flange I3. Said flange at the bottom end of the panel is welded to a steel channel iron [4 which may be bolted to the flooring.

Fixed against rear face ll of the analyzer panel are filter units M and N, functioning to remove impurities in the gas sample flowing through the apparatus, which might vitiate the Hopcalite in the reaction cell, or otherwise interfere with the proper operation of the analyzer. These filter units contain replaceable charges of filter material and differ only in size and the type of filter material contained.

Filter unit N, Figs. 11 and 12, comprises a cylindrical shell i5, externally threaded at its lower end as at It and capped at the upper end by a circular end piece [1 welded therein as at is. Said end piece is centrally drilled and tapped as at is to receive tubular gas conduit 28 welded therein as at 2|. The side wall of shell 35 near threaded end H is drilled as at 22 and fitted with a short conduit coupling piece 23 welded therein.

The filter charge unit comprises a cylindrical container 24 slidable within cylindrical shell l5 and provided with a pair of internal semi-circular ring grooves 25 and 26 at one end and a similar pair of ring grooves 27 and 28 at the other end. Said pairs of ring grooves are fitted 4 with readily removable retainer ring springs 29 and 33, and 3| and 32, each having circular wire screen pieces 33 and 34, respectively, thereinbetween disposed.

In filter unit N, container 23 is filled with a central charge of activated charcoal 35 and glass wool end plugs 36 and 31 serving to retain the charcoal charge in place. Said charge is easily replaceable by removing one of the outer retainer ring springs and its adjacent screen.

Container 24 is disposed in cylindrical shell up against a circular gasket 38, preferably of rubber, fitted against the inner side of end piece 11. Said container is held in place by the compressional force imparted by coil spring 39 held thereagainst by internally threaded cap 40 threaded on threads 16. Said cap is provided with a hexagonal stud M in its outer face for easy removal with a small wrench. Said cap is further provided with a circular rubber gasket 42 to insure an air-tight closure of the filter shell.

It will now be evident that all of the gas sample drawn in through coupling 23 and out through conduit will find passage only through lower screen 36, filter material 3'5, and 36 and upper screen 33.

Filter unit M (Fig. 13) is similar in construction to filter unit N, above described, except that it is somewhat smaller in size and has in its filter charge container 24 a charge of steel wool 43 at its lower half and glass wool 44 at its upper half.

Referring to Fig. 1, it is shown that sampling tube S connects to coupling 23 of filter unit M. Filter units M and N are interconnected by conduit 45. Conduit 20 of filter unit N is connected to orifice block Q as by coupling 56 (Fig. 14).

Said orifice block comprises a rectangular block, preferably of brass, drilled from each end nearly to the center of the block as as 41 and s8, said drilled holes being coaxially aligned. The central portion between the inner ends of said drilled holes is coaxially drilled and threaded to a smaller diameter as at 49 for retaining screwed therein an orifice member 58. Said orifice member comprises an axially drilled rod 5| slotted at one end for receiving a screwdriver as at 52 and provided with external threads 53, centrally located along its outer length, for cooperative engagement with threads 49 in the orifice block.

Drilled holes 41 and 48 are internally threaded at their outer ends as at 5A and 55, hole 4? being threaded to accommodate coupling unit 46 and hole 48 being threaded to accommodate a plug 56. It is through this plug opening that orifice member 56 can readily be removed, by means of a screwdriver, from the orifice block for cleaning. (See dashed line representation of removed plug and orifice member.)

Said orifice block is provided with a pair of holes 5? and 58 drilled from one side of the block and communicating at right angles with holes 41 and 48 respectively. Said holes are internally threaded at their outer ends as atv 59 and Si) to receive connector units El and 82 respectively. Said orifice block is further provided with a pair of mounting holes 53 and 6d through which screws and (it may secure the block to panel face i l.

The fiow rate of the sample gas pumped through the analyzer is regulated to about 8.5 liters per minute by a Cartesian manostat C, fixed to the front of panel face 12, having a fioat 6'! acting as a throttling valve (Fig. 2). The pressure to operate said fioat is developed across the orifice member 5| in orifice block Q and connected to said Cartesian manostat by'conduits 68' and 69. Such a Cartesian manostat is manufactured and sold by the Emil Greiner Co. of N. Moore St, New York city, and described in detail in their Bulletin No. ICM96 titled Automatic Vacuum and Pressure Control.

Means is provided to continuously indicatethe rate of flow of the sample gas through the analyzer. To this end there is provided a flowmeter F mounted on front face :2 of the analyzer panel and connected to the output of Cartesian manostat' C by a conduit ill. Said flowmeter is preferably one of the type having a tapered and calibrated glass tube ll within which there is a float l2 which rises within the tube in pro portion to the rate of gas flow through the tube. Such a flowmeter is manufactured and sold by the Brooks Etotometer'Co. of Lansdale, Pennsylvania, and is described in their drawing No. 1012.

Heater block H is set on a bracketed shelf B and held in place by the connections of its gas conduits and electrical cables to the rest of the analyzer system. Said shelf comprises a bottom plate is fixed between grooved side pieces Id and 15 mounted against and extending from back face II of the analyzer panel and supported at their outer ends by brace pieces iii and H. Said brace pieces are fixed at one end as by screws "iii and iii to rear panel H and by screws 83 and 8! and their other ends to side pieces M and 75 respectively.

Heater block H comprises a cylindrical metallic container 32 open at its top end. The inner walls of said container are insulated by glass fiber insulation layers at the bottom and around the inside wall (Figs. sand 5). Disposed within said insulated container is a cast aluminum heater member 35, cylindrical in shape and having cast within it several coils of a stainless steel tubing as, in helical formation coaxial with said cylindrical heater member. Said heater member is provided with a central, cylindrical cavity 81 extending from its top and nearly to its bottom end. Stainless steel tubing 8% terminates at its upper end in an upwardly extending arm 88 for connection to the down-stream end of flow meter F. The other end of said stainless steel tubing terminates within the cavity and at the bottom thereof in a slide connector block 85 to which it is welded as by weld (Fig. 7).

Heater member 85 is electrically heated by means of a fiber glass insulated nichrome wire heater element 9i wound around its outside cylindrical surface and so spaced as to provide ere tra heat input near the top of the c iled tubing 86 where the sample gas flowing is coldest. The ends of said heater winding are brought out to a terminal strip 92 mounted on the top of said heater member Where they connect to wires in a cable connecting to the electrical heat control circuit hereinbelow described.

To provide for the installation of remotely controlled temperature operated devices, hereinbelow described, heater member 85 is further provided near its outer cylindrical surface with three bored holes 94, 95, 98, extending from the top of said member vertically down for a distance of three or four inches.

Reaction cell unit 91 (Figs. 4, and 9) disposed within cavity 8? of heater member 85 comprises a chemically inert, cylindrical casing of low heat conductivity 9%, externally threaded at each end as at 99 and Hill to provide for assembly to up per and lower metallic, internally threaded cap members I01 and I02 respectively. Said casing is preferably machined of the plastic material tetrafiuoroethylene resin, known commonly as Teflon, manufactured by E. I. Du Pont de Nemours Co. Inc. Cap member I02 has welded to it as at IE3 at a central opening therein a length of tubing Ill-l provided with an annular groove near its outer end in which is disposed a heat resistant silicone composition 0 ring gasket I05. Such a gasket can be procured from Linear, Inc. of State Road and Levick Street, Philadelphia 35, Pa.

Cap member llll has welded to it as at l-J'l at a central opening therein a length of tubing Hi8 provided with a couplin member H19 at its remote end. Intermediate said last cap member and coupling member on said length of tubing, coaxially disposed and welded thereto as at H3, is a circular mounting number Ill provided equidistantly spaced within a concentric circle with three mounting holes I I2, and a pair of feed through insulators 1 i3 and I [4.

Reaction cell unit 9'! is easily assembled to the heater member 86 by placing the end of tubing its into close-fitting cylindrical opening H5 in slide connector block 89 and sliding it down until the underside of mounting member Ill seats against the top of the heater member 36 to which it is held in place by machine screws I I6 through the holes H2 in said mountin members and screwed into tapped holes I I! in said heater member (Fig. 5). The sealing action of O ring hi6 squeezed between opening H5 in the connector block 39 and the inner circuinierence'of groove i535 serves to insure a gas-tight connection for sample gas flow through the reaction cell unit.

There is disposed against shoulder H8 within casing of the reaction cell unit a thermopile asserjsly HS comprising a length of plastic tubing are having a plurality of equidistantly spaced longitudinal grooves it! in which are disposed alternately Chromel wires I22 and constantan wires 23, the adjacent dissimilar wires being twisted and silver-soldered to form thermo-electric junctions I25 and i25'a-t the upper and lower respectively of said thermopile assembly. thermopile unit has adjacent its lower end for the purpose of insulating thermo-electric junctions I25, an annular plastic gasket a (Figs. 9 and 10). The output terminals [2% and I2? of said thermopile are threaded through closefitting holes E28 and 125} into the interior of tubing iZG, insulated as by insulation pieces and it! and fed through holes 132 and I33 to the outside of casing 38. Said thermopile conductors external oft he casing as are insulated by insulation pieces I34 and i35 and terminate the underside of feed-through insulators i i3 and li l, being held thereto respectively as by retaining nuts I36 and i3'l.

There is fitted against internal shoulder (38 near the upper end of casin 5.2 a circular wire mesh piece I39 held in place thereagainst as by a circular retainerspring Mt positioned in an nular groove lei. The lower end of casin is enclosed by a circular wire mesh piece [:32 retained in place by a pair of circular retainer springs i 33 and Hit disposed in grooves :45 and Hit respectively. lhe space between wire mesh pieces I39 and 52 is filled to about halfway down, so as to surround cold thermocouple junctions 2:2, with a chemically inert material Ml such as pumice, and the remainderis preferably filled, so as to surround hot thermo-couple junctions I25, with a carbon monoxide catalyst I48, known to the trade as Hopcalite.

Fig. 1'7 shows a modified reaction cell unit differing from that shown in Fig. 9 in that casing 98 is provided with an internal groove 2% disposed in which is a layer of fiber glass insulation 2 serving to further insulate thermopile unit H9 from the rest of the reaction cell. The only other difference is that hot thermopile junctions 266 are distributed longitudinally about the axis of Hopcalite material I41. This is done because it has been found that in prolonged use the Hopcalite near the bottom becomes less active, and the center of reaction and consequent heat proceeds gradually toward the top end of the Hopcalite. By this method of distributing the hot thermopile junctions along the vertical axis, equal average thermopile voltages will result for a given gas conservation even in prolonged use.

Connection is made to the thermopile by a two wire cable M9 entering the side of container 32 and connecting to the outer terminals of feed through insulators H3 and IM (Figs. 1 and 4).

Cover means is provided to further insulate the heater member 85. The same comprises a pair of complementary semi-circular skirted cover parts I and i5i each insulated at its under side by layers of fiber glass insulation i532 and I53 retained in place as by clamps i5 3 and 55- held in place respectively as by screws I56 and i5?. Openings I53, I59 and I653 are provided between said cover parts for entrance of conduit tubes 86 and I88 and cables of the thermally operated devices hereinbelow described (Figs. 4 and 6).

Coupling member W8 is connected to a conduit IGI mounted against the inner face ii of the analyzer panel. Said conduit terminates in con nection to a length of fiexible tubing 152 which in turn is connected to a rotary vacuum pump I63. Said pump is driven by an electric motor I55 connected in an electric circuit hereinbelow described.

Means is provided to regulate and control the electrical power input to heater block H so that it remains substantially at a constant level corresponding to a block temperature of about 145 C. after the initial warm-up period.

To this end there is provided an electrical circuit device having circuit elements mounted within a metal box I65 fixed to rear face i I of the analyzer panel. Said circuit comprises relays i be and iS'I, rheostats I63 and its, a voltage regulation transformer Ilfi, an auto-transformer lii, thermostatically controlled switches H2 and i2 3, fuse I'M and switch IE5 connected in circuit with heater coil 95 (Fig. 16).

Relay ibt, having an energizing coil 556a, has associated with it a switch comprising fixed contact arm I662; and movable contact arm i550, normally open, but adapted to be closed when said relay is energized. Also associated with said relay is a single-pole, double-throw switch, comprising fixed contact arms liatd and Ifite, and movable contact arm i551. Said movable contact arm is normally in electrical contact with fixed contact arm IESd, but upon energization of said relay is adapted to break contact therewith and move into electrical contact with fixed contact arm I66e.

Relay I51, having an energizing coil it'ia, has associated with it a switch comprising fixed contact arm It'Ib and movable contact arm itic, normally open, but adapted to be closed when said relay is energized. Also associated with relay I6! is a switch comprising fixed contact arm IBM and movable contact arm IBIe, normally closed, but adapted to be open-circuited when said relay is energized.

Thermostatically controlled switch 572 comprises a fixed contact arm H21) and a bi-metallic heat sensitive switch arm element I'iZa. Said switch is adjusted to close-circuit at a temperature of 145 C.

Thermostatically controlled switch H3 comprises a fixed contact arm H'3c and a movable contact arm I'Ifiid controlled by a diaphragm lite connected by capillary tube H321 to heat sensitive bulb 573a located within heater block II. Said switch, adjusted to open-circuit at a temperature substantially higher than the operating temperature, may be one of those shownand described in the bulletin entitled Robertshaw Electric Thermostat of the Robertshaw-Fulton Controlls Company, Youngwood, Pennsylvania.

Fixed contact arm ififib is connected by wire I15 to fixed contact arm Hill) and by wires H6 and i235 to one terminal of energizing coil Itiia. Movable contact arm IGSc is connected by wire IT! to movable contact arm IB'Ec, by wires Ill and I to fixed contact arm ISte is connected by wire I it to movable contact arm I8'Ie and one terminal of rheostat I68 and by wires H8 and IEI E to contact arm 568a of said rheostat. Movable contact arm ISG is connected by wire I19 to one terminal of heater element ti. The remaining terminal of said heater element is connected by wires I88 and 85 to one terminal each of energization coils I860, and Ifiia, and by wires I88, I89 and I83 to the source of alternating current supply ACG.

The remaining terminal of rheostat its is connected by wire 653 to fixed contact arm IEid and to the tap on auto-transformer iii. Movable contact arm HM is connected, by wire I84 in series with fuse lit and switch H5 to the source of supply ACI-I.

One terminal of each of the transformer winding I'Ifla, Hub, and iila, is connected through wire I83 to ACG. The remaining terminal of primary winding I'Ifia is connected by wire 582 to fixed contact arm lite. The remaining terminal of secondary winding Heb is connected by wire I9!) to one terminal of rheostat I63, the other terminal of said rheostat being connected by wire I92 to the remaining terminal of winding lilo; of auto-transformer Eli and by wires i232 and iSi to contact arm ifita of said last rheostat.

it is evident that when switch 515 is first closed, heater element 9i will be connected directly across the input for initial maximum warm-up heating. This circuit is from ACE, through closed switch HE, fuse Ii i, wire I 3 normally closed switch Iii-id, i136, wires I8! and Hit, normally closed switch 55d, Ififif, wire iii), through heater element 9! and wires 583, I35 and its to ACG. The heat input during this period of rapid warm-up may be in the order of ten times that normally supplied the block in operation, so that little time is wasted in bringing the apparatus up to the operation temperature. When heater block 35 is at atemperature of about 145 C., thermally operated switch I 72a, i'izb closes, completing the energization circuit to relay it? from ACH, through now closed switch I715, fuse i'ii, normally closed switch I'ISd, lite, wires I and 535, now closed switch I'IEb, E1251, wire I 87, through energization coil 561a and wires act, 58%, and 83 to ACG. The energization of said relay will in turn complete an energization circuit to relay I56, this circuit being from ACH, through now closed 9 switch I15, fuse I14, normally closed switch 11311, I136, wires I8I, I89 and ill, now closed switch I611), I670, wires I16 and I85, through energization coil I'86a and wires I86, I88, I89 and I83 to ACG. The operation of relay IE will complete an independent energization circuitfor itself through its switch Itfib, I650, said circuit being from ACH, through now closed switch I75, fuse I14, normally closed switch II3d, 36, wires IBI, I80 and I'll, now closed switch I661), I660 wires I76 and I85 through energization coil vHider and wires I86, I88, I89 and I83 to ACG.

It will thus be evident that relay I6 5, once energized, will become de-energized only upon subsequent opening of either thermally controlled switch I ltd, II3e or apparatus supply switch H5. Further, it should be noted here that switch I'i3c, I136, set to operate at a temperature above the normal operating temperatures of the heater block is a safety device to cut on" the circuit only if the heater block for any reason should reach an abnormally high temperature.

From an inspection of the circuit diagram it will now be evident that after the completion of the warm-up cycle heater element 9| will be energized at the lower regulated potential furnished at the tap of auto-transformer I! I. This circuit can be traced from said tap through wire I53, thence through either closed switch ifil'd, Ilile or rheostat I38 (as is hereinbelow explained) to wire '58, thence through now closed switch 155e, I56 Wire I19, through heater element SI, and wires I88, I89 and M3 to ACG.

Constant voltage transformer nu, known in the art, is connected in the ordinary manner to energize auto-transformer I'II. Rheostat IE9 is furnished as a course adjustment of the lower operating voltage supplied at the tap on autotransformer I'll to heater element 9|.

Two methods of heat control are possible with the above circuit, the constant power input method and the constant temperature method.

Under ordinary conditions the constant power input method is preferred and consists in adjusting rheostat I as so that auto-transformer I II supplies just enough power into the heating element to keep the block at a temperature sufiiciently above the operating temperature of thermally operated switch I'I2a, I72?) so that slight temperature variations in the block due to ordinary room temperature changes will not allow said switch to open. Under these conditions relay I6? remains energized, switch Ifi'id, IG'Ie, is open-circuited and rheostat I 58, is included in the series circuit to said heater element. It should be noted here that if for some reason the temperature of the heater block, under constant power input operation, becomes less than the actuation temperature of switch IlZa, I'IZb, said switch will open-circuit and interrupt the above detailed energization circuit to relay I 61, thereby closing switch Ifi'ld, [51c and shunting out rheostat Hi3. This in turn will increase the voltage supplied to the heater element and, consequently the power input supplied, so as to raise the temperature of the block.

In the constant temperature control method rheostat I 69 is adjusted so that auto-transformer Il'I supplies just enough power into the heating element to keep the block at a temperature close to the operating temperature of thermally operated switch Ilia, IIZb, so that the slight temperature variations in the block due to room temperature change will cycle said switch. From the above description it will be evident that such cycling will-operate to change the power input 'to said heater block so that a constant value of average temperature of said block is maintained. With this type of operation the adjustment of rheostat I68 serves to control the voltage or power differential supplied to said heater element.

In order that visual indication may be had of the temperature of heater block 35 there is mounted in front analyzer panel I2 a remote reading thermometer 202 having its temperature measuring bulb 203 located in hole in said block.

Thermopile H9 is connected by wires I95 and I95 in the cable I49 to photo-electric recorder R. Said recorder may be one such as type CES Photoelectric Potentiometer Recorder manufactured by General Electric Co. of Schenectady, New York, and described in their catalog No. GEI1S731B. Said recorder may be energized as by Wire I83 to ACG and. wire I91 in series with fuse I98, switch I39 and wire 208 to ACE.

In the lower part of Fig. 16 it is shown how motor I84 connected to vacuum pump It! may be wired in the ordinary manner to a source of 3 phase A. C. supply through a switch 291.

It will thus be seen that there is provided an apparatus in which the several objects of this invention are achieved and which is well adapted to meet the conditions of practical use. As vari ous possible embodiments might be made of the above invention, and as various changes might be made in the embodiment above set forth, it is to be understood that all matters herein set forth are shown in the accompanying drawings is to be interpreted as illustrative and not in a limiting sense.

Having thus described our invention we claim as new and desire to secure by Letters Patent:

1. In an electrical device for heating a reaction cell block, the combination comprising an electric heating element adapted to heat said block, a first relay, a second relay, means comprising a primary circuit for said element, to supply said heating element initially with a predetermined amount of power for rapid heating of said block to operating temperature, a thermostatically controlled switch in said primary circuit in series with said first relay, said switch including a thermostatic element positioned adjacent to the heating element to be heated by said heating element,

circuit means controlled by said switch to energize said relay when said thermostatic element reaches a predetermined temperature, circuit mean controlled by the energization of said first relay to energize said second relay, a secondary circuit including a transformer, and means controlled by the energization of second relay to cut on" the primary circuit from the heating element and to connect said element into said secondary circuit to reduce the power input to said heating element.

2. In an electrical device for heating a reaction cell block. the combination comprising an electric heating element adapted to heat said block, a first relay, a second relay, means comprising a primary circuit for said element, to supply said heating element initially with a predetermined amount of power for rapid heating of said block to operating temperature, a thermostatically controlled switch in said primary circuit in series with said first relay, said switch including a thermostatic element positioned adjacent to the heating element to be heated by aid heating element, circuit means controlled by said switch to energize said relay when said thermostatic element reaches a predetermined temperature, circuit means controlled by the energization of said first relay to energize said second relay, a secondary circuit including a transformer, and means controlled by the energization of the second relay to cut off the primary circuit from the heating element and to connect said element into said secondary circuit to reduce the power input to said heating element, and circuit means operative to maintain energization of said second relay upon de-energization of said first relay, upon opening of said thermostatic switch due to cooling of said thermostatic element.

3. In an electrical device for heating a reaction cell block, the combination comprising an electric heating element adapted to heat said block, a first relay, a second relay, means comprising a primary circuit for said element, to supply said heating element initially with a predetermined amount of power for rapid heating of said block to operating temperature, a thermostatically controlled switch in said primary circuit in series with said first relay, said switch including a thermostatic element positioned adjacent to the heating element to be heated by aid heating element, circuit means controlled by said switch to energize said relay when said thermostatic element reaches a predetermined temperature, circuit means controlled by the energization of said first relay to energize said second relay, a secondary circuit including a transformer, and means controlled by the energization of said second relay to cut off the primary circuit from the heating element and to connect said element into said secondary circuit to reduce the power input to said heating element, said reducing means comprising a voltage reducing auto-transformer energized by a voltage regulator transformer and means to adjust the output voltage of said autotransformer.

4. In an electrical device for heating a reaction cell block, the combination comprising, an electric heating element adapted to heat said block, a first relay, a second relay, means comprising a primary circuit for said element, to supply said heating element initially with a predetermined amount of power for rapid heating of said block to operating temperature, a thermostatically controlled switch in said primary circuit in series with said first relay, said switch including a thermostatic element positioned adjacent to the heating element to be heated by said heating element, circuit means controlled by said switch to energize said relay when said thermostatic element reaches a predetermined temperature, circuit means controlled by the energization of said first relay to energize said second relay, a secondary circuit including a transformer, means controlled by the energization of said second relay to cut oil the primary circuit from the heating element and to connect said element into said secondary circuit to reduce the power input to said heating element, means operative to maintain energization of said second relay upon de-energization of said first relay upon opening of said thermostatic switch due to cooling of said thermostatic element, and means controlled by the said deenergization of said first relay to increase the power input to said heating element to a degree greater than said reduced power output but not as great as said predetermined power output.

5. In an electrical device for heating a reaction cell block, the combination comprising, an electric heating element adapted to heat said block,

means comprising a primary circuit for said element to supply said heating element initially with a predetermined amount of power for rapid heating of said block, a secondary circuit including a transformer, thermostatically controlled means including a thermostatic element positioned adjacent to said element for heating by said heating element to cut ofi the primary circuit from said element and to connect said element into said secondary circuit to reduce the power input to said heating element when said thermostatic element reaches a predetermined temperature, and means controlling said primary and secondary circuits to cut out the power supply to the heating element upon increase of temperature of the thermostatic element to a predetermined temperature above the first mentioned predetermined temperature.

6. In combination, a reaction cell block, an electric heating element to heat said block, means comprising a primary circuit to supply a predetermined power to said heating means, a secondary circuit including a transformer, thermostatically controlled means including a thermostatic element positioned adjacent to said element to be heated by said heating element, to cut off the primary circuit from said element and to connect said element into said secondary circuit to reduce the power output to said heating element when said thermostatic element reaches a predetermined temperature, means dependent upon opening of said thermostatic switch due to cooling of said thermostatic element to increase the power output to the heating element above said reduced power output but below said predetermined power output, and means controlling the primary and secondary circuits to cut out the power supply to the heating element upon increase of temperature of the thermostatic element to a predetermined temperature above the first mentioned predetermined temperature.

'7. A reaction cell formed with a passage, means to pass a gas through said passage, an electric heating element of fixed operating resistance for heating said cell to increase the temperature of the gas passing through said passage, means to supply said heating element with a predetermined amount of power for heating said cell at a predetermined rate to a predetermined temperature, thermostatically controlled means to reduce the supply of power to the heating element when said cell attain a predetermined temperature whereby to continue heating the cell but at a lesser rate than it was heated up to said predetermined temperature, and means to maintain the reduced supply or power substantially constant, said last means including means to add a resistance to the power supply circuit.

8. A reaction cell formed with a passage, means to pass a gas through said passage, an electric heating element of fixed operating resistance for heating said cell to increase the temperature of the gas passing through said passage, means to supply said heating element with a predetermined amount of power for heating said cell at a predetermined rate to a predetermined temperature, thermostatically controlled means to reduce the supply of power to the heating element when said cell attains a predetermined temperature whereby to continue heating the cell but at a lesser rate than it was heated up to said predetermined temperature, means to maintain the reduced supply of power substantially constant, said last means including means to add a 13 resistance to the power supply circuit, and means decendent upon the reduction of the temperature of the cell below said predetermined temperature to short said resistance from said pewer supply circuit.

References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,121,979 Collins 1 Dec. 22, 1914 1,224,321 Philip et a1 May 1, 1917 1,343,353 Colby Aug. 10, 1920 1,349,379 Hester Aug. 10, 1920 Number 14 Name Date Thomson Aug. 2 1, 1920 Lamb et a1. May 16, 1922 Simpson 1 Jan. 10, 1933 Kennedy May 15, 1834 Forde Oct. 1, 1935 Canfield May 11, 1937 Price Apr. 19, 1938 Rowe Oct. 28, 1941 Burch June 17, 19 17 Hulbert Aug. 30, 19 19 Bushway Jan. 31, 1950 Eaton et a1 Sept. 5, 1950 

